US2438836A

US2438836A - Pulse echo distance measuring system

Info

Publication number: US2438836A
Application number: US404845A
Authority: US
Inventors: Wolff Irving
Original assignee: RCA Corp
Current assignee: RCA Corp
Priority date: 1941-07-31
Filing date: 1941-07-31
Publication date: 1948-03-30
Anticipated expiration: 1965-03-30

Description

Much 30.1948. l. woLFF 2,438,

PULSE ECHO DISTANCE MEASURING SYSTEM Filed Julys'l, 1941 l li 'Y fue* Patented Mar. 30, 1948 UNITED STATES ,PATENT OFFICE PULSE lECHO DISTVRCIE MEASURING SYS Irving WoliL'Merchantville, N. J., assignor to Radio Corporation of America, a corporation ot Delaware Application July 31, 1941, Serial No. 404,845

. curate for altitudes of the order about 50 or more meters, certain difficulties are experienced in measuring accurately distances of less than 50 meters. One method of indicating the pulse propagation time is to start a cathode ray timing trace at the instant the initial pulse is radiated and to deect the rayalong another coordinate at the instant the echo pulse 1s receivedy/ The initial pulse and the echo pulse appear as`serrations in the cathode ray trace. Since even the shortest pulses have some duration, it follows that the serrations have appreciable width. For altitudes between, say, 50 meters and 10,000 meters, the pulses may. have a duration of the order of `0.1 to 1.0 microsecond. It is not only diillcult to radiate substantial amounts of energy in a shorter pulse but it is equally diillcult to generate shorter pulses. A pulse time of 0.1 microsecond is equivalent to the pulse traveling 30 meters which corresponds to twice the distance to be measured. Furthermore, the initial pulse will occupy meters of .the scale and it will be difficult to distinguish the initial pulse and the echo 18 Claims. (Cl. 343-13) object is to provide means in a pulse echo device for indicating altitudes above a predetermined limit as a function of pulse propagation times indicated by means including the pulse envelopes and below said predetermined altitude as a function of pulse propagation times indicated by means including the individual components of the pulses. A still further object is to provide an improved method for measuring distances as a function of pulse propagation Vtimes whereby pulses of the order of a microsecond duration pulse which will overlap for distances up to 30 meters. Furthermore, in the described system, since the pulse envelope is used, it may be difcult to select any precise point on the envelope as a reference mark. It might be thought that increasing the scale length would be a solution. However, increasing the scale length is accompanied by a corresponding increase in the width oi the pulse trace so that the ratio is not im proved.

Thus it appears that in any pulse echo distance measuring method the pulse envelope length is the factor determining the shortest measurable distance. It is therefore an object of this invention to provide means for measuring accurately short distances and the rate of change of distance by means of a pulse echo system in which the components of the pulse are used in place of the pulse envelope. Another object is toprovide means in a pulse echo system for dividing the distance 'scale by applying timing potentialsderived from the outgoing pulses. An additional may be used for both long and short distances and for indicating the rate of change of distance.

The invention will be described by referring to the accompanying drawing in which Fig. 1 is a block diagram illustrating an embodiment of the invention; Figs. 2 and 3 are graphs of the long and short distance indications, respectively; and

Fig. 4 is a schematic circuit diagram of a detector and limiter which are used in one embodiment of the invention.

Referring to Fig. 1, a pulse generator or keyer i is connected to a transmitter 3 and a sweep generator E. The sweep generator may be connected through a voltage divider 40, an amplier 42, and by means of a double throw switch 'l to the horizontal deilecting elements 9 cfa cathode ray tube il. It should be understoodthat the voltage divider lll and amplifier d2 may be omitted, and the sweep generator 5 connected directly to the switch The output of the transmitter is applied to an antenna I3 which is preferably made directive by means of one or more reiiectors i5. One or more directors i1 may be added, although in many practical installations they may be omitted. A portion oi the transmitter output is directly or indirectly applied to a detector and limiter i@ which will be hereinafter described. The detector may be connected through an amplifier 2i arid the switch 'i to the horizontal deflecting elements 9.

An R.F. amplifier 23 may be connected by a transmission and delay line 24, to the transmitting antenna I3 or to a separate antenna 25 which receives a signal of low amplitude and of proper phase from the transmitter. The R.F'. ampliner may be connected through av double pole switch 21 to the vertical deecting elements 29 of the cathode raytube Il. The R.F. ampller is connected to a first detector and local oscillator and hence to an I.F. amplifier 33. Theoutput of the I.F. amplifier 33 is applied to a second detector 35 which may be connected through the switch 2l to the vertical deflecting elements of the cathode ray tube Il. The cathode `ray tube is energized and biased in the conventiqnal manner by a suitable power source which is not shown. While a superheterodyne receiver circuit has been shown, other amplification and detection circuits may be used. l

When the switches 1. 21 are in the position shown, and the voltage divider 44 and amplifier 42 are omitted, the operation is as follows: The cathode ray is swept horizontally in synchronism with each outgoing pulse. The outgoing pulses arereceived after reflection from the earth or other object whose distance is to be determined.

The received echo pulses are amplified and detected. The detected pulses are applied to deflect the cathode ray vertically, as shown in Fig. 2. This method of operation is that of the conventional pulse echo system and is used for measuring distances in excess of about 50 meters. Since the pulse duration may be of the order of 1 microsecond, it follows that the pulse envelope or length will correspond to 150 meters on the distance scale.

The switches 1, 21 are connected to the upper terminals 4I, 43, respectively, when measuring distances of less than about 50 meters. In this connection the sweep generator 5 is not used but in its place the outgoing pulses are rectified by a detector and limiter I9. The phase of the outgoing pulses may be determined by the point at which the detector is connected or`coupled to the transmitter. The detector I9 includes a resistorcapacitor network having a time constant which is long compared to the pulse time but short compared to the sweep time of the generator 5. For example, if the pulse time is 1 microsecond, the time constant should be of the order of 3 or 4 microseconds. Preferably, the sweep rate should be uniform or approximately linear, The uniform sweep may be substantially obtained by limiting the amplitude of the detector output. The limited amplitude leads to a uniform charging rate for the capacitor and hence a uniform sweep.v

At the same time the ray is swept horizontally bypotentials from the rectler, the directly received radio frequency currents of carrier frequency are applied to the vertical deiiecting elements 29. The phase or timing of the directly received radio frequency currents is regulated by the time delay introduced by the delay line 24. The radio frequency components deflect the cath- 0de ray in the vertical direction at the carrier frequency as shown by the trace 39. These variations of the trace, occurring at constant frequency, form an accurate timing scale which may be calibrated in distance units. For example, if the carrier frequency is 500 megacycles, the period between crossings of the base line will be .001

. microsecond or 30 centimeters of pulse propagation which is equivalent to 15 centimeters of actual distance between thel transmitter and the object. The amplitude of the traces due to the directly received radio frequency currents is preferably adjusted so that the trace is`about 1/4' inch high. It should be understood that only the first part of the sweep and timing potentials are used.

The reflected or echo pulse will be received and amplified at radiofrequency. The amplified radio frequency currents are applied to the ver tical deecting elements so that the directly received radio frequency4 currents and the indirectly received radio frequency currents combine to produce a vertical deflection trace 4| "which is greater or less than the timing trace as the diphase, respectively. In the graph of Fig. 3 the timing pulse and the echo pulse radio frequency currents are represented as in phase. Ii the two radio frequency currents had been of opposite phase the trace 4I would have been of lesser amplitude. In either event the beginning of the combined tracelil is referred to the beginning of the timing trace to indicate distance, The overlapping of the two traces does not interfere with reading the distance of the reflecting object. and the timing trace kprovides an accurate electrical calibration of time or distance.

When the device is used as an altimeter. another advantage is found in the short distance scale, For example, when landing, the aircraft pilot may not only observe the altitude of the craft, but the changing altitude will cause the phase of the echo pulses to vary so that the trace 4i will slowly increase and decrease in amplitude. The rate of such increase or decrease indicates the rate of descent or ascent. In like manner when the aircraft is taking off, the rate of climb will be indicated. In either ascending or descending it is only necessary for the observer to count the slowly varying changes in height of the combined trace to determine the rate of change of altitude. Thus a single means indicates simultaneously the altitude or distance and the rate of change of altitude or distance,

In the described system -the fast sweep is derived from the outgoing pulse by rectifying and limiting. A simpler, but less well synchronized, method may be used. The rate of sweep depends upon the rate of change of deilecting potential, The slow sweep voltage may be amplled and, in the absence of overloading, the sweep rate will be increased by the same ratio as the voltage is amplified. Since higher voltage is not required, a fraction of the sweep voltage from the sweep generatorA 5 may be derived from the voltage divider 40, and may be amplified by the amplifier 42 to provide the fast sweep for the short distance scale.

The details of the rectifier an-d limiter I9 are shown in Fig- 4 in which the resistors 5| are inserted in the leads to the antenna transmission line to limit the power taken by the detector and limiter network. The remote terminals of the resistors are shunted by a gas discharge tube4 resistor network is chosen as described above.A

In the detector and limiter network a selected portion of the transmitted pulse energy is limited, rectified and applied to the time constant circuit. The charging of the capacitor 6I provides the sweep potential. The discharge of the capacitor provides the return line potential for the sweep.

Other details of this pulse echo system are not included in this specification as the circuits and elements thereof are disclosed in the prior art, as, for example, in the Physical Review, vol. 28, page 554 (Sept. 1926). l

Thus the invention has been disclosed as an improved pulse echo distance measuring system which is especially useful as a sensitive altimeter. For rlong distances the envelope of the pulse is usedto deflect a cathode ray beam to indicate the reception of the echo puise. The beam is4 cluding in combination a r pulse generator connected to said transmitter for' yalso deilected over a distance scale by a sweep voltage which is synchronized with the outgoing pulses. For short distances, the distance sweep deilect the beam back and forth across'the distance scale to apply timing indications. The echo 4 pulse is amplified and its radio frequency components combine with the R.F. timing swings thereby to indicate the distance of the pulse reflecting objectl If the distance is changing the indications vary slowly so that the rate of change of distance may be determined.

l claim as my invention:

1. A pulse echo distance measuring system including, in combination, a pulse transmitter, a pulse generator connected to said transmitter for applying keying pulses thereto, a pulse receiver responsive directly to pulses from said transmitter and to pulses reflected from objects whose distances are to be measured, a cathode ray tube including a distance scale and elements for deflecting said ray along said scale and additional elements for def-lecting said ray along another scale, means for deriving from said pulse trans- `mitter sweep voltages synchronized with said keying, means for applying said sweep voltages to said distance scale deflecting elements, and means for applying-high frequency voltages to said `additional elements to deflect said ray along said other scalelat a predetermined frequency.

2. A pulse echo distance measuring system inpulse transmitter, a

applying keying pulses thereto, a pulse receiver responsive directly to pulses from said transmitter and to pulses reflected from objects whose distan-ces are to be measured, a cathode ray tube including a distance scale and elements for deflecting said ray along said scale and additional elements for deflecting said ray along an amplitude scale, means for deriving from said pulse transmitter sweep voltages synchronized with said keying, means for applying said sweep voltages to said distance scale deflecting elements,4

and means including said pulse receiver for deriving high frequency components fro'msaid reilected 'pulses and for applying said high frequency components to said additional elements to deflect said ray along said amplitude scale and to indicate reception of said reflected pulses and the `distance of the reflecting object.

3. A pulse echo distance measuring system including, in combination, means for radiating pulses of radio frequency energy, means for receiving said pulses after reflection from an object whose distance vis' to be measured, means for nected to said transmitter deriving from said pulses timing currents synchronized with said pulse radiation, an indicator including a timing meansand signal responsive means, means for applying said timing currents to said timing means, and means including said receiving means for applying to said 4signal responsive means high frequency energy of the Waveform received directly from said radiating means and said high frequency energy of the wave form received anfter reflection from an object whose distance is to be measured.

4. A system according to claim 3 including switching means connected to said timing means rents from said pulse received after reflection, and'means including said switching means for l and to said signal responsive means, means for generating a timing voltage slower than said tim- Y ing currents, means for deriving envelope cursaid pulses after reflection from said object, a l

cathode ray indicator 4including distance and amplitude scales, means for deilecting said cathode ray`a1ong said distance scale in synchronism with the radiation of said pulses, means for deflecting said ray along said amplitude scale by the radio frequency components of said pulsesto apply time marking to said indicator, and means including said receiving means for deflecting additionally said ray along said amplitude scale as a function of the received reflected pulses.

6. A distance measuring system according to claim 5 including a sweep voltage generator synchronized with said pulse generating means, a detector effectively connected to said receiving means for deriving currents corresponding to the envelope of received reilected pulses, and switching means for connecting said sweep voltage generator for deecting said ray on said distance scale` and said detector for deilecting said ray on said amplitude scale of said cathode ray indicator for indicating echo pulses from objects at greater than a predetermined distance.

7. A radio frequency pulse echo system including, in combination, a, sweep voltage generator, a keyer synchronized with said generator, a transmitter connected to said keyer, means confor radiating pulses of radio frequency energy, a cathode ray tube including means for deflecting said ray along a distance scale as a function of said sweep voltage, and means for deflecting said ray along an amplitude scale, means for amplifying said sweep voltages whereby shorter distances may be indicated on said distance scale, a radio-receivertected pulses derived by reilection from objects located beyond said predetermined distance.

8. A pulse echo distance system including means for generating a pulse of radio frequency energy, means for deriving from said pulse energy a, sweep potential, .a cathode ray tube including elements for deilecting said rayvalong two different coordinates, means for applying said sweep potential to said deflectinlg elements to deflect said ray along one coordinate, means for receiving said pulse energy directly and after reflection from an object whose distance is to be determined, and means for applying said directly received energy to deflect said ray along a second coordinate to form a timing trace and for applying said indirectly received energy to defleet said ray along said second coordinate to indicate the reception of an echo pulse.L

ject winch includes the steps of responding to said radio frequency,

`for deflecting said ray to g of 'radio frequency energy,

9. The method of indicating on a cathode ray tube the distance of a radio pulse reflecting obradiating pulses of radio frequency energy, deriving a synchronizing current from said radiated'pulses, applying said current to said cathode ray tube to deflect said ray to indicate distance, deriving the radio frequency components of said radiated pulses to provide ray deflecting forces for said cathode ray tube, applying said Yforces to deflect said cathode ray for indicating time intervals correceiving saidV pulses afterr reflection from said object, and applying said received pulses to said cathode ray tube indicate the propagation time required for said pulses to travel to said ob'- :lect and from said object to the source of said pulse' radiation. 1

,10. The method of indicating on a cathode ray tube the distance of a radio pulse reflecting object which includes the steps of radiating pulses deriving a synchronizing current from said radiated pulses, applying said current to said cathode ray tube to deflect said cathode ray to indicate distance, deriving the radio frequency components of said radiated pules to provide ray defiecting forces for said cathode ray tube, applyingr said forces to said cathode ray for indicating time intervals corresponding to said radio frequency, receiving said pulses after reflection from said object, amplifylng the radio frequency components of said received pulses, and applying said amplified radio frequency components to said tube to deflect said cathode ray tp indicate the propagation time required for said pulses to travel to said object and n to indicate from said object to the source of said pulse radia-f tion and hence the distance of said object.

11. The method of indicating on a cathode ray tube the distance of a radio pulse reflecting object which includes the steps of radiating pulses of radio frequency energy, rectifying said pulses to derive a sweep current in synchronism with said pulses, applying said sweep current to said tube to deflect saidyray, applying the radio fre quency components of said radiated pulses to said tube to apply timing deflections to said deflected ray, receiving said pulses after reection from said object, and applying said received pulses to said tube thus to deflect said ray to indicate the distance of said object.

12. The method of indicating on a cathode ray tube the distance 0f a radio pulse reflecting ob ject which includes the steps ofnadiating pulses of radio frequency energy, rectifying said pulses to derive a sweep current in synchronism with said pulses, applying said sweep current to said tube to deflect saidray, applying the radio frequency components of said radiated pulses to said tube to apply timing deflections to said deflected ray, receiving said pulses after reflection from said object, amplifying the ra'dio frequency components of said received pulses, and applying the amplified radio frequency components to said tube to deflect said ray thus to indicate the distance of said object.

13. Themethod of indicating on a cathode ray tube the distance of a radio puise reflecting object which includes the steps of radiating pulses of radio frequency energy, generating sweeplvoltages in synchronism with said pulse radiations, amplifying said sweep voltages to derive a faster sweep voltage, applying said faster sweep voltage to said tube to deflect said ray, applying the radio frequency components of said radiated pulses to vsaid tube to deflect said ray at predetermined indistance of said object.

14. The method of indicating on a cathode ray tube the distance of` a radio pulse reflecting ob- "Ject which includes the stepsof radiating pulses of radio frequency energy, generating sweep voltagesin synchronism with said pulse radiations, amplifying said sweep voltages to derive a faster sweep voltage. applying said amplied voltages to said tube to deflect said ray, applying the radio frequency components of said radiated pulses to said tube to deect said ray at predetermined intervals corresponding to known distances, receivingl said radiated pulses after reflection from said object, amplifying the radio frequency components of said received pulses, and applying said amplified radio frequency components to said tube to deflect said ray thus the distance of said object.

15. A pulse echo system. including in combination means for radiatingl pulses of radio frequency energy, means for receiving said pulses directly" and after reflection from a body whose distance is to be measured, means for deriving a component signal from said radiated pulses, an indicator for indicating simultaneously the distance of said body and the timerate of change of said distance, means for applying said directly `received pulses and said reflected received pulses to said indicator, and means for applying said component signal derived from said radiated pulses to said indicator to produce therein a timingwave .varying in amplitude at the frequency of said radiated radio frequency energy and to superimpose thereon the carrier frequency components of said reflected received pulses to indicate the distance of said body by the position of said superimposed pulses with respect to said f timing wave.

16. A pulse echo distance and rate of change of distance indicating system including means for generating pulses of radio frequency energy, means for radiating said pulses toward an object whose distance and rate of change .of distance are to be indicated as functions of time, means for receiving said pulses after reflection from said object, a cathode ray indicator having distance and amplitudescales, means for defiecting said cathode ray along said distance scale in synchronism with the radiation of said pulses, means for deflecting said ray along said amplitude scale by the radio frequency components of said pulses to apply time marking to said indicator, and means including said receiving means for vdeflecting additionally lsaid ray along said amplitude scale as a function of the received reflected pulses so that the time marked position of said additional deflection indicates the dis- 'tance of said object and the rate of change of the amplitude of said additional deflection indicates the rate of change of distance of said object.

17. A pulse distance measuring system includwave form as the high frequency energy waves of said received pulses, means for deriving a sweep vvoltage from said pulses of high frequency energy, an indicator, and means for applying to said indicator said sweep voltage and for applying directly said first and second signals whereby the phase of said rst and second signals may be compared to determine said distance.

18. The method of determining distance which includes radiatingy pulses of high frequency energy, receiving said pulses after they have traversed the medium in which said distance is to be measured, deriving a first and a second signal of the same wave form as the high frequency waves of said received pulses, deriving a sweep voltage from said .pulses of high frequency energy, and utilizing said sweep voltage and directly utilizing said first and second signals to. deter-- mine distance as a function of the phase of said first and second signals.

IRVING WOLFF.

` REFERENCES CITED The following references are of record in the file of this patent:

UNITED sTATEs PATENTS Number Name Date 1,924,174 Wolf Aug. 29,1933 2,227,598 Lyman et. al Jan. 7, 1941 FOREIGN PATENTS Number Countryl Date 111,594 Australia Mar.y 19, 1939